I'm working on a problem out of Griffith's Intro to QM 2nd Ed. and it's asking to find the bound states for for the potential $V(x)=-\alpha[\delta(x+a)+\delta(x-a)]$ This is what I'm doing so far:
\begin{equation} \mbox{for $x\lt-a$:}\hspace{1cm}\psi=Ae^{\kappa a}\\ \mbox{for $-a\lt x\lt a$}\hspace{1cm}\psi=Be^{-\kappa x}+Ce^{\kappa x}\\ \mbox{and for $x\gt a$:}\hspace{1cm}\psi=De^{-\kappa a} \end{equation}
However, this is what the solution reads: \begin{equation} \mbox{for $x\lt a$:}\hspace{1cm}\psi=Ae^{-\kappa a}\\ \mbox{for $-a\lt x\lt a$}\hspace{1cm}\psi=B(e^{\kappa x}+e^{-\kappa x})\\ \mbox{and for $x\lt-a$:}\hspace{1cm}\psi=Ae^{\kappa a} \end{equation}
Can someone explain what I'm doing wrong - why they are getting the coefficients they are - and what I should be doing? Maybe go over the general way of approaching these kind of problems? I'm also wondering why they don't have the case for $x>a$?
${\bf New}$ ${\bf Question}$
After this I am trying to figure out what $\Delta\left(\frac{d\psi}{dx}\right)$ is. Integrating the potential part of SWE and taking the limit as $\epsilon$ approaches $\pm a$I get: \begin{equation} \Delta\left(\frac{d\psi}{dx}\right)=-\frac{2m}{\hbar ^2}\left[\alpha\psi(a)+\alpha\psi(-a)\right] \end{equation} but the solution reads $\Delta\left(\frac{d\psi}{dx}\right)=-\frac{2m\alpha}{\hbar^2}\psi(a)$ I think I'm close but not sure how they got their result. Do you see what I'm doing? Can you correct where I made any mistakes?
